JP2003130342A - Combustion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a combustion device with manually continuously variable capacity. SOLUTION: A main burner 120 for ignition is arranged near a pilot burner 110 and is supplied with gas via no gas governor. A plurality of sub burners 130 and 140 are supplied with gas via a variable gas pressure type gas governor 180. A switching means 190 is manually operable to switch the number of sub burners supplied with fuel gas. The combination of the switching means and the variable gas pressure type gas governor enables a continuous manual change in combustion capacity within a wide range. The main burner is insusceptible to a setting value of regulated gas pressure in the variable gas pressure type gas governor. A nozzle is arranged just in front of each burner, and a nozzle diameter for the main burner is set smaller than that for the sub burners, so that even under a fluctuation in supply gas pressure, a change in input quantity is reduced and a stable ignition performance is ensured even from a minimum supply gas pressure.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a combustion device having a plurality of burners.

[0002]

2. Description of the Related Art In water heaters, bathtubs with showers, etc. that do not have an electrically controlled gas amount adjusting mechanism such as a proportional control valve,
The hot water temperature is adjusted mainly by adjusting the water flow rate. In addition, a large change in water temperature depending on the season is handled by manually switching the number of burners to which fuel gas is supplied.

[0003]

However, in the above-mentioned one, since the gas capacity can be changed only in a stepwise manner by switching the number of burners, the amount of water for obtaining an appropriate temperature can be adjusted only in a stepwise manner. , There were cases where it was not possible to discharge hot water at an appropriate temperature and amount. Figure 1
As shown in 0, there are four burners, for example, a maximum capacity of 8.5.
In the case of the hot water heater of No. 3, the burner switching configuration switches the number of burners to 4, 2, 1 and 3 levels of capacity (large 8.5, medium 4.3, small 2. No. 1), in order to obtain the tap water temperature of 42 ° C. when the incoming water temperature is 23 ° C., the amount of tapping water is 5.6 liters per minute in the capacity (see FIG. 8). The amount of hot water discharged from the shower is weak because the hole diameter of the shower plate is constant.
It is too small to use as a shower. On the other hand, if the capacity is switched to high, the amount of hot water discharged will be 11.2 liters per minute,
In a place where the supply water pressure is low, such as in the top floor of an apartment where water is supplied by an elevated water tank, this amount of water cannot be obtained, and as a result, it may not be possible to obtain comfortable hot water at 42 ° C. See also FIG.
Even in the case of a water heater with a maximum capacity of 6.5, for example, where there are three burners without the portion surrounded by the broken line, the burner switching mechanism switches the number of burners to three, two, and one The amount of water used to obtain water was naturally adjusted only in stages, making it inconvenient to use.

The present invention has been made by paying attention to the problems of such conventional techniques, and an object thereof is to provide a combustion device capable of continuously changing the capacity manually.

[0005]

The gist of the present invention for achieving the above object resides in the inventions of the following items. [1] In a combustion apparatus having a plurality of burners, a switching unit (190) for switching the number of burners to which the fuel gas is supplied based on a manual operation, and a gas amount of the fuel gas supplied to the burner to a manual mode. A combustion apparatus, comprising: an adjusting means (180) that can be changed based on an operation, wherein the switching means (190) and the adjusting means (180) can be used together to manually adjust the heating power.

[2] Downstream of the adjusting means (180),
The combustion apparatus according to [1], characterized in that the switching means (190) is provided.

[3] In a combustion apparatus having a plurality of burners, a main burner (120), one or more sub-burners (130, 140), a pilot burner (110) for spark ignition, and a switching means (190). ) And adjusting means (180), and the adjusting means (180) changes the gas amount of the fuel gas supplied to all or part of the sub-burners (130, 140) based on a manual operation. The switching means (190) switches the number of fuel gases supplied to the sub-burners (130, 140) based on a manual operation, and the main burner (120). Is supplied with fuel gas without passing through the adjusting means (180) and is capable of transferring fire from the pilot burner (110). Combustion apparatus characterized by being arranged in the vicinity of Na (110).

[4] Downstream of the adjusting means (180),
The combustion apparatus according to [3], characterized in that the switching means (190) is provided.

[5] In a combustion apparatus having a plurality of burners, an adjusting means (180) for changing the amount of fuel gas supplied to the burner based on a manual operation and the adjusting means (180) are used. One or more sub-burners (130, 140) supplied with fuel gas, a main burner (120) supplied with fuel gas without going through the adjusting means (180), and a pilot burner (11) for ignition.
0) and the main burner (120) is arranged in the vicinity of the pilot burner (110) so that the fire can be transferred from the pilot burner (110).

[6] The adjusting means (180) stabilizes the gas pressure of the fuel gas supplied to the burner to a predetermined set value and can change the set value based on a manual operation. Combustion apparatus according to [1], [2], [3], [4] or [5], which is a gas governor.

[7] The adjusting means (180) stabilizes the gas pressure of the fuel gas supplied to the burner to a predetermined set value and can change the set value based on a manual operation. A gas governor for supplying the fuel gas to the main burner (120) without a gas governor for stabilizing the gas pressure of the fuel gas to a predetermined set value,
A nozzle for narrowing the flow passage cross-sectional area is provided in the front stage of each burner, and a nozzle (16
The combustor according to [3], [4] or [5], wherein the nozzle diameter of 2) is smaller than the nozzle diameter of the nozzles (172, 173) provided in the preceding stage of the sub-burner.

[8] The combustion amount of the main burner (120) when the fuel gas is supplied at the assumed maximum gas pressure does not exceed the maximum combustion amount allowed by the main burner (120). The combustion device according to [7], characterized in that the nozzle diameter of the nozzle (162) provided in the front stage of the main burner is set to be large.

The present invention operates as follows. By operating the switching means (190), the number of burners to which the fuel gas is supplied can be manually switched. Further, by operating the adjusting means (180), the gas amount of the fuel gas supplied to the burner can be continuously and manually changed within a predetermined range. And the switching means (190) and the adjusting means (180)
By using and together, it becomes possible to manually and continuously adjust the thermal power control over a wide range.

That is, in the case of an atmospheric pressure burner, a large T
Since the DR (turndown ratio) cannot be obtained, there is a certain limit in limiting the amount of fuel gas supplied to each burner. Therefore, the combustion amount cannot be greatly changed only by adjusting the gas amount by the adjusting means (180). Therefore, by switching the number of burners and adjusting the gas amount, it is possible to continuously and extensively adjust the thermal power.

In the case where the switching means (190) is provided downstream of the adjusting means (180), one adjusting means (18) is provided.
In 0), the amount of gas supplied to a plurality of burners can be adjusted, and the device configuration can be simplified. In addition, adjusting means (18
By placing 0) upstream of the switching means (190), it is possible to prevent a discontinuous region from occurring in the gas amount adjustment range.

For example, the gas supply amount to each burner is 30
Adjusting means (180) if it can be squeezed up to%
When one burner is provided downstream of the adjusting means (180), a switching means (190) is provided upstream of the adjusting means (180), and the burner to which the fuel gas is supplied is switched to only one burner downstream of the adjusting means (180). The firepower can be adjusted within the range of 0.3 to 1.0 of the maximum burner capacity. Next, adjusting means (18
0) and one burner that does not pass the adjusting means (180) downstream so that the fuel gas is supplied in total, the capacity can be adjusted in the range of 1.3 to 2.0. become. Therefore, even if the number of burners is switched by the switching means (190), the gas amount cannot be continuously changed in the range of 1.0 to 1.3.

On the other hand, when the switching means (190) is arranged downstream of the adjusting means (180), the switching means (190) has a capacity of 0.
In the range of 3 to 1.0, it becomes possible to adjust in the range of 0.6 to 2.0 when there are two pieces, the ranges of both are overlapped, discontinuous areas are not formed, and continuous from the minimum to the maximum. It becomes possible to adjust the firepower.

Further, a main burner (120), one or more sub-burners (130, 140), a pilot burner (110) for spark ignition, a switching means (190),
With the adjusting means (180), the adjusting means (1
80) manually adjusts the amount of fuel gas supplied to all or some of the sub-burners (130, 140), and the switching means (190) controls the sub-burners (130, 140).
In 140), the number of fuel gas supplied is manually changed. The main burner (120) is arranged in the vicinity of the pilot burner (110) so as to be supplied with fuel gas without passing through the adjusting means (180) and to be able to transfer fire from the pilot burner (110).

Thus, the pilot burner (110)
The main burner (12
0) is supplied with the fuel gas without going through the adjusting means (180), therefore, regardless of the setting of the adjusting means (180), that is, even if the adjusting means (180) is set to reduce the gas amount. It is possible to secure stable ignition.

In the above structure, the switching means (19
0) does not necessarily have to be provided. That is, 1 or 2 that is supplied with fuel gas via the adjusting means (180)
The above sub-burners (130, 140) and adjusting means (1
It may be provided with a main burner (120) which receives the supply of fuel gas without going through 80) and a pilot burner (110) for igniting. In this case, the switching means (1
90), so sub-burners (130, 140)
The minimum combustion amount increases as the number of
The gas amount can be continuously adjusted from the minimum combustion amount to the maximum combustion amount. Main burner (120)
Since the fuel gas is supplied to the engine without going through the adjusting means (180), it is possible to secure a reliable ignition due to a fire transfer from the pilot burner (110).

As the adjusting means (180), a gas pressure variable type gas governor capable of stabilizing the gas pressure of the fuel gas supplied to the burner to a predetermined set value and changing the set value based on a manual operation. Good to use. Normally, a gas governor is used to absorb fluctuations in gas pressure,
If the governor is of a variable set gas pressure type, the cost of the device can be reduced as compared with the case where a separate adjusting means (180) is provided in addition to the gas governor.

A gas pressure variable type gas governor is used as the adjusting means (180), and the main burner (1
Fuel gas is supplied to 20) without passing through a gas governor. A nozzle for narrowing the flow passage cross-sectional area is provided in the front stage of each burner, and the nozzle diameter of the nozzle (162) provided in the front stage of the main burner is set to the sub-burners (130, 140).
It is smaller than the nozzle diameter of the nozzle.

In the case of having a gas governor, the nozzle diameter may be set so that the burner has the maximum combustion amount at the lowest gas pressure, but the main burner (12) without the gas governor.
In the case of 0), fluctuations in the gas pressure cannot be coped with unless the burner has the maximum combustion amount at the maximum gas pressure.

Therefore, by making the diameter of the nozzle provided in the preceding stage of the main burner (120) smaller than the diameter of the nozzle for the sub-nozzle, it becomes possible to set the maximum combustion pressure at the maximum gas pressure. Also, by making the nozzle diameter small, the amount of change in the combustion amount with respect to the gas pressure of the main burner (120) can be suppressed to a small amount, so even if the maximum combustion amount is set at the maximum gas pressure, it is stable at the minimum gas pressure. It is possible to obtain the amount of combustion that ensures the generated ignition.

When the fuel gas is supplied at the expected maximum gas pressure, the main burner (120) burns within a range in which the combustion amount of the main burner (120) does not exceed the maximum combustion amount allowed by the main burner (120). If the nozzle diameter of the nozzle for () is set to a large value, it is possible to secure almost the same amount of combustion at the maximum gas pressure as when all gas burners are equipped with a gas governor, and to secure more stable ignition even at the minimum gas pressure. can do.

[0026]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Various embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a main part of a combustion apparatus 100 according to a first embodiment of the present invention in a water heater having three burners and a hot water supply capacity of, for example, No. 6.5. In the case of four burners, there is a third sub-burner 145 indicated by the dotted line in the figure provided in parallel with the burner 140, and the hot water supply capacity is, for example, 8.5. Combustion device 10
0 is a pilot burner 110 that serves as a pilot fire, and a main burner 120 arranged near the pilot burner 110.
And the first sub-burner 1 provided in parallel with the main burner 120.
30 and a second sub-burner 140. Here, the same burner is used for the main burner 120, the first sub-burner 130, and the second sub-burner 140. The pilot burner 110 is ignited by an ignition means (not shown) and the valve a is opened, so that the burner 120 is ignited by the pilot burner 110.
The burner 130 is ignited by the fire of 20 and the fire is transferred in order.

The combustion device 100 supplies the supplied fuel gas to the main burner 120, the first sub-burner 130 and the second burner 130.
It has a gas distribution chamber 150 for distribution to the sub-burner 140. The inside of the gas distribution chamber 150 is the first gas chamber 1
60 and the second gas chamber 170. First gas chamber 1
Gas inlet portions 161 and 171 are opened in the 60 and the second gas chamber 170, respectively.
Fuel gas from the supply source is sent to the respective gas chambers through 1, 171.

An outlet portion of the fuel gas is opened in the first gas chamber 160, and the main burner 120 is connected to the outlet portion via the first nozzle 162. A gas pressure variable type gas governor 180 is provided in the vicinity of the gas inlet 171 formed in the second gas chamber 170. Second gas chamber 170
Two fuel gas outlets are opened on the downstream side of the variable gas pressure type gas governor 180, one of which has the first sub-burner 130 via the second nozzle 172 and the other of which has one opening. Is connected to the second sub-burner 140 via a third nozzle 173.

The fuel gas flowing in from the gas inlet 171 is supplied to the first sub-burner 130 and the second sub-burner 140 via the gas pressure variable type gas governor 180. In the second gas chamber 170, the fuel gas that has passed through the gas pressure variable type gas governor 180 is supplied to the first sub-burner 1
A burner switching mechanism 1 for switching between sending to only the first sub-burner 130, sending to both the first sub-burner 130 and the second sub-burner 140, and not sending to either burner.
90 is provided.

Inside the variable gas pressure type gas governor 180,
A diaphragm 181 divides the chamber into two chambers, one of which is connected to the gas inlet portion 171 and has an opening serving as a gas outlet portion to the downstream side where the first sub-burner 130 and the like exist, and a peripheral edge of the gas outlet portion. A valve seat 182 is formed in the. A valve body 183 of the gas governor is arranged outside the gas outlet portion so as to face the valve seat 182, and a support arm extending from the center of the valve body 183 is connected to the diaphragm 181 through the opening. That is, the valve body 1
83 is suspended by the diaphragm 181 via the support arm 184.

The space of the rear surface of the diaphragm 181 where the valve body 183 is suspended by the support arm 184 is maintained at the atmospheric pressure by the opening 188, and one end of the coil spring 185 is applied to the rear surface of the diaphragm. The other end of the coil spring 185 is in contact with the spring pedestal 187 that moves back and forth in accordance with the turning operation of the fine adjustment knob 186.

The fuel gas flowing in from the gas inlet 171 flows out to the downstream side where the burner switching mechanism 190 exists through the gap between the valve seat 182 and the valve body 183. When the gas pressure of the fuel gas flowing from the gas inlet portion 171 to the gas pressure variable type gas governor 180 becomes high, the diaphragm 181 is pushed to the coil spring 185 side,
Therefore, the gap between the valve seat 182 and the valve body 183 becomes narrower. Further, when the gas pressure of the fuel gas becomes low, the force of the coil spring 185 becomes stronger and the gap between the valve seat 182 and the valve body 183 widens.

Therefore, even if the gas pressure of the supplied fuel gas fluctuates, the gas pressure on the downstream side of the gas pressure variable type gas governor 180 is maintained at a constant regulated gas pressure. Since the regulation gas pressure depends on the force of the coil spring 185 pushing the diaphragm 181, the regulation gas pressure, that is, the gas pressure variable type gas governor 180, is moved by rotating the fine adjustment knob 186 to move the spring pedestal 187 forward and backward. It is possible to change the setting of the gas pressure on the downstream side of.

The burner switching mechanism 190 includes a switching valve body 191 having a substantially frustoconical shape having a gas guide passage 195 therein and the like.
A valve seat body 192 into which the switching valve body 191 is fitted, a spring 193 that presses the switching valve body 191 so as to closely contact the inside of the valve seat body 192, and a rotation target shaft extending from the switching valve body 191 A capability switching knob 194 is provided. The valve seat body 192 is provided with a total of three openings in the upper and lower portions and in a portion communicating with the second nozzle 172.

As shown in FIG. 9, the switching valve body 191 has a T
There is a letter-shaped through-passage, and it is further second from the T-shaped intersection.
A through passage is provided so as to communicate with the nozzle 172. When the ability switching knob 194 is turned to the position shown in FIG. 9A,
The fuel gas from the upstream does not flow into the through passage of the switching valve body 191, and the fuel gas is supplied only to the main burner 120 of the plurality of burners. When the capacity switching knob 194 is turned to the position shown in FIG. 9B, the fuel gas from the upstream is supplied to all of the main burner 120, the first sub-burner 130, the second sub-burner 140, and the third sub-burner 145.
When the capacity switching knob 194 is turned to the position shown in FIG. 9 (c), the fuel gas from the upstream is connected to the main burner 120 and the first burner 120.
It is supplied only to the sub-burner 130.

Therefore, in the case of the four-portion construction having the third sub-burner, the number of burners can be switched to one, two or four by operating the capacity switching knob 194. . Also, there is no third sub-burner 3
In the case of this configuration, the number of burners can be switched to one, two, or three by operating the capacity switching knob 194. For example, in the case of a four-burner configuration, if the capacity switching knob 194 is set to the position shown in FIG. 9A, the capacity becomes No. 2.1, and the capacity becomes No. 8.5 in FIG. 9B. In 9 (c), the ability will be 4.3. In the case of a three-burner configuration, the capacity switching knob 1
When 94 is set to the position of FIG. 9 (a), the ability of No. 2.2 is obtained, and in FIG. 9 (b), the ability of No. 6.5 is obtained.
In (c), the ability is 4.3.

Next, the first nozzle 162 and the second nozzle 17
The nozzle diameters of the second and third nozzles 173 will be described.
The fourth nozzle 174 has the same diameter as the third nozzle 173.

The upper graph 210 of FIG. 2 shows the relationship between the supplied gas pressure (P ₁ ) and the gas pressure (P ₂ ) at the inlet side of each of the nozzles 162, 172, 173. The graph 220 shows the relationship between the supplied gas pressure (P ₁ ) and the combustion amount (Q) of each burner.

The solid line 211 of the upper graph 210 indicates the supplied gas pressure and the first nozzle 162 for the main burner 120.
The relationship with the gas pressure on the inlet side is shown. First nozzle 16
Fuel gas is supplied to 2 without going through the gas governor,
The inlet gas pressure of the first nozzle 162 and the supply gas pressure become equal.

The solid line 212 and the dotted line 213 of the upper graph 210 show the relationship between the supplied gas pressure and the gas pressure at the inlet side of the second nozzle 172 for the first sub-burner 130. Of these, the solid line 212 is the gas pressure variable type gas governor 1.
80 is the characteristic when the set value of the regulated gas pressure in 80 is the highest (set to the maximum set value), and the dotted line 213 adjusts the fine adjustment knob 186 to set the regulated gas pressure to the lowest (set to the minimum set value). It shows the characteristics of the case. The gas pressure on the inlet side of the third nozzle 173 for the second sub-burner 140 is the same as the gas pressure on the inlet side of the second nozzle 172.

By passing through the gas pressure variable type gas governor 180, when the supply gas pressure is below the regulated gas pressure,
The inlet-side pressure P ₂ of the nozzles 172 and 173 becomes substantially equal to the supply gas pressure, and the supply gas pressure is the gas pressure variable type gas governor 1.
In a region equal to or higher than the regulated gas pressure of 80, the inlet side pressure P ₂ of the nozzles 172 and 173 is maintained at the regulated gas pressure which is set almost regardless of the supply gas pressure.

Assuming that the supply gas pressure P ₁ fluctuates between the minimum supply gas pressure Pmin and the maximum supply gas pressure Pmax specified by JIS2093 in relation to the fuel gas supply amount and demand of the gas company, the supply gas pressure Regardless of the gas pressure to the nozzle, the gas pressure at the inlet side of the nozzle 172 when the gas pressure variable type gas governor 180 is set to the maximum setting value, that is, the gas pressure variable type gas governor at the maximum setting value is set. It suffices if the regulated gas pressure of 180 (maximum regulated gas pressure) becomes substantially equal to the minimum supply gas pressure Pmin.

Considering the TDR of the burner, for example, when TDR = 3.3, it is necessary to secure at least 30% of the maximum input. Therefore, when the input of the first sub-burner 130 is set to the maximum input (100%) when the variable gas pressure type gas governor 180 is set to the maximum setting value, the variable gas pressure type gas governor 180 is set to the minimum value. The regulated gas pressure (minimum regulated gas pressure) of the gas pressure variable type gas governor 180 at the minimum set value is set so that the input when set to a value is approximately 30% of the maximum input.

As shown by the solid line 212 and the dotted line 213 of the upper graph 210, the gas pressure variable type gas governor 180 is passed through, so that when the supply gas pressure is below the regulated gas pressure, the inlet pressure of the nozzles 172 and 173 is reduced. P ₂ becomes substantially equal to the supply gas pressure, and in the region where the supply gas pressure is equal to or higher than the regulated gas pressure of the gas pressure variable type gas governor 180, the inlet side pressure P ₂ of the nozzles 172 and 173 is
The regulated gas pressure is almost set.

As a result, the gas pressure variable type gas governor 180
Is set to the maximum setting value, the first sub-burner 130, the second
The combustion amount of the sub-burner 140 changes as shown by the solid line 222 in the lower graph 220, and the supply gas pressure is almost the same as the regulation gas pressure (the minimum supply gas pressure Pmin. However, since there is a pressure loss, the minimum supply gas pressure is actually the minimum supply gas pressure. As a slightly lower value, for example, a value that is about 95% when converted into an input is shown. Therefore, for example, Pmin × 0.8 = regulating gas pressure is more preferable) until the supply gas pressure is reached. The combustion amount increases in accordance with the above, and when the supply gas pressure becomes equal to or higher than the minimum supply gas pressure Pmin, the combustion becomes almost constant, that is, the combustion with the maximum input. When the gas pressure variable type gas governor 180 is set to the minimum setting value, the lower graph 22
As indicated by the dotted line 223 of 0, in the region where the supply gas pressure is equal to or higher than the minimum regulation gas pressure, the constant combustion amount is about 30% of the maximum input.

On the other hand, since the main burner 120 is supplied with the fuel gas without passing through the gas governor, the combustion amount thereof changes substantially in proportion to the supply gas pressure. Therefore, JI
When the maximum supply gas pressure Pmax determined by S is set so as to be the maximum input which is the upper limit of the burner combustion amount, it is possible to design the burner so that the burner capacity is sufficiently exhibited. Here, for example, the main burner 120 is the first
Since the burner is of the same type as the sub-burner 130 and the second sub-burner 140, the combustion amount of the main burner 120 at the maximum supply gas pressure Pmax is the first sub-burner 130.
It is sufficient if the combustion amount becomes equal to the maximum combustion input amount of the second sub-burner 140.

Each nozzle diameter is set so that the above conditions are satisfied. Here, the burner combustion amount is obtained by the following equation.

[0048]

[Equation 1] In the above equation, Q is the gas flow rate and the unit is Nm ³ / h (1
Nm ³ is gas 1 at 0 ° C. and atmospheric pressure = 101.3 Kpa
m ³ ). D is the nozzle diameter (units are millimeters and mm), k is the flow coefficient, d is the gas specific gravity when the specific gravity of air is 1, P ₂ is the nozzle gas pressure (the unit is Pascal,
Pa). For example, k is set to a predetermined value such as 0.8, and d is set to the type of fuel gas. Gas type is 1
In the case of 3A-0, d = 0.67. 13A
-If 0, 46200 kilojoules (KJ) = 1 Nm
It will be ³ .

With regard to the first sub-burner 130 and the second sub-burner 140, when the nozzle gas pressure P ₂ is the maximum regulated gas pressure of the gas pressure variable type gas governor 180, it is sufficient if the combustion amount reaches the required maximum input Qmax, and therefore it is known. The nozzle diameters of the second nozzle 172 and the third nozzle 173 can be obtained by substituting the minimum supply gas pressure Pmin corresponding to the maximum regulation gas pressure as k and d and the nozzle gas pressure P ₂ into the equation (1).

The main burner 120 has a nozzle gas pressure P ₂
Is the maximum supply gas pressure Pmax, the maximum combustion amount Qmax
Therefore, the nozzle diameter of the first nozzle 162 can be obtained by substituting Pmax into the equation (1) as the known k and d and the nozzle gas pressure P ₂ .

Now, let us consider concrete numerical values in the case where the hot water supply capacity of four burners is set to 8.5. The hot water supply capacity of 8.5 is the amount of heat required to raise the temperature of 8.5 liters of water by 25 ° C per minute,
The combustion amount per burner is 8.5 x 25 x 60 ÷
0.83 × 4.2 ÷ 4 = 16129 KJ / h (kilojoules per hour). Note that 0.83 in the formula is thermal efficiency. The minimum supply gas pressure is 1K pascal and the maximum supply gas pressure is 2.5K pascal. Also, the gas type is 13A-0.
When the above combustion amount is converted to a gas flow rate, 4620
Since 0KJ = 1 Nm ³ , it becomes 0.3491 Nm ³ / h.

First, the nozzle diameter for the subburner is obtained.
Since the sub-burners 130, 140, 145 allow the maximum input to be obtained at the minimum supply gas pressure, Q = 0.3491 Nm ^{3 /} h, k = 0.8, d =
0.67, 1 KPa which is the minimum supply gas pressure is substituted as P ₂ . As a result, D = φ1.79 mm can be obtained (the answer calculated by equation (1) is a fraction, but φ1.79 mm because the price becomes high when the drill diameter is 1/100 mm or less.
mm. On the contrary, when φ1.79 mm, the combustion amount obtained from the equation (1) is 16076 KJ / h).

The main burner 120 has the highest supply gas pressure.
Since it is only necessary to maximize the input,
In formula (1), Q = 0.3491 Nm^Three/ H, k = 0.
8, d = 0.67, P_TwoIs the highest supply gas pressure as
Substitute 2.5 KPa. This allows the main burner
D = φ1.43mm is obtained as the nozzle diameter (φ1.4
3, P _Two, The combustion amount at 2.5 KPa is 16222 KJ /
h).

By setting the nozzle diameters in this way, each burner has the maximum input (actually 16076 × 3 + 16222KJ) at the maximum supply gas pressure.
/ H, which will be shown below as 16076), so that the same combustibility can be obtained as in the case where the fuel gas is supplied through all four gas governors. On the other hand, at the minimum supply gas pressure, the three sub-burners are 15272
It burns at KJ / h (equivalent to about 95% of 16076, 5% is loss due to pressure loss), and the main burner is 10260 KJ.
/ H (corresponding to about 64% of 16076 KJ / h).

Therefore, in the case of the four burners as a whole, the input down of all four burners can be suppressed to about 8% as compared with that through the gas governor. The above value of 8% down is 0.95 for all four gas governors, assuming that the standard gas pressure P ₂ = 2K pascal is 1.0, and one main burner does not go through the gas governor. In the remaining three sub-burners, the fuel gas supplied by the gas governor is 0.
It is based on becoming 87.

Next, the fire transfer will be examined. The conditions for the fire transfer include a pilot burner (usually flame tip 1
The area of the corresponding flame port surface of the receiver side burner (main burner in the case of the present application) and the amount of gas supplied from the flame port. In other words, as a condition of the fire transfer, it is difficult to transfer the fire between the pilot burner and the main burner at the minimum supply gas pressure with a small gas supply amount. Further, when all four gas pressure variable type gas governors are passed, this corresponds to the case where the governor is set to the minimum setting value. There are, for example, 17 corresponding flame openings between the main burner and the sub-burner, so that the flame is easily transferred even at the minimum supply gas pressure where the gas supply amount is small. Therefore, considering the case where the first main burner also passes through the gas variable type gas governor, the governor is set to the minimum setting value (30% of the maximum input, P ₂ = 90).
When it is set to Pascal, the combustion amount of the first main burner becomes 5334 KJ / h (68% down), and there is a possibility that the flame transfer between the pilot burner and the main burner may not be performed well. On the other hand, in the present invention where the first main burner does not pass through the gas governor,
Since the combustion amount is 60 KJ / h (down by 33%), sufficiently good fire transfer can be performed. The percentage of the above combustion amount reduction is the combustion amount of the main burner in the case where all four gas through the gas governor when the combustion amount 15272KJ / h when the supply gas pressure is the minimum supply gas pressure (1K Pascal) is 1. Is 0.32, which is 0.67 in this embodiment.

In other words, even if the position of the gas pressure fine adjustment knob 186 arbitrarily set by the customer is the minimum set value, or even if the supply gas pressure becomes the minimum supply gas pressure, the first important one for the fire transfer. Since the value of burner's ability down is not large,
Ignition performance at the lowest supply gas pressure can be maintained. This ignition performance has the same structure, and is particularly effective in appliances that support many gas types.
In the case of gas species such as C and L3, the superiority of ignition performance is particularly exhibited.

In the above example, the maximum input (100%) of the burner was obtained at the maximum supply gas pressure, but the burner performance is such that even if the input is increased to about 120%, good combustion can be achieved. Since it is usually used, the nozzle diameter may be set such that the burner has a maximum input (100%) at a supply gas pressure that is somewhat lower than the maximum supply gas pressure.

In FIG. 3, the solid line 301 shows the combustion characteristics of the burner passing through the gas governor, and the broken line 302 is
It is a combustion characteristic when the input is set to be 100% at the maximum supply gas pressure (2.5K pascal). The nozzle diameter at this time is φ1.43 mm. The solid line 303 is 100% when the supply gas pressure is 2K Pascal
Is a graph showing the relationship between the supplied gas pressure (P ₁ ) and the combustion amount (Q) of each burner in the case of becoming the input of
The nozzle diameter at this time is φ1.51 mm. Solid line 30
In the case of 3, the combustion amount is 100% when the supply gas pressure is standard (Pstd = 2 KPa). Therefore, when the maximum supply gas pressure is 2.5 KPascal, the combustion amount is 113%.

The combustion amount is 1 which is the upper limit of the burner.
Since it is 20% or less, combustion is possible without any particular problem. When all four burners are burnt at 120%, no problem occurs in the burner combustion performance, but as in the above example, only one burns at 113% at the maximum supply gas pressure, and If the three are 100%, no problem occurs. In this way, the main burner has the maximum input (100
%), The supply gas pressure does not necessarily have to be the maximum supply gas pressure, and a slight increase or decrease is allowed. In addition,
The calculation and design may be performed as described above even when the hot water supply capacity of the three burners is 6.5.

Next, the operation of the combustion apparatus according to this embodiment will be described. Hot water supply capacity of 6.5 with three burners
In the case of No. No., the case where the main burner brings the maximum input (100%) at the maximum supply gas pressure will be described. To set the combustion amount to the minimum, the capacity switching knob 194 of the burner switching mechanism 190 is set. Is manually operated to stop the supply of the fuel gas to the first sub-burner 130 and the second sub-burner 140. In this state,
Fuel gas is supplied only to the main burner 120, and the combustion amount is equivalent to one burner.

To increase the combustion amount, the capacity switching knob 19
4 is manually operated to supply the fuel gas to the first sub-burner 130 in addition to the main burner 120. By manually operating the fine adjustment knob 186 of the gas pressure variable type gas governor 180, the combustion amount of the first sub-burner 130 increases or decreases within the range of 0.3 to 1 when the maximum combustion amount is 1. Therefore, the supply pressure of the fuel gas is the maximum supply gas pressure Pmax.
In the case of, since the main burner 120 also has a combustion amount of about 1, the main burner 120 and the first sub-burner
The book makes it possible to manually adjust the combustion amount in the range of 1.3 to 2.0. In addition, between 1.0 and 1.3, an appropriate hot water temperature is obtained by adjusting the amount of water.

Capacity switching knob 1 of burner switching mechanism 190
When the fuel gas is supplied to the first sub-burner 130 and the second sub-burner 140 in addition to the main burner 120 by manually operating 94, the variable gas pressure type gas governor 180 is adjusted to adjust the first sub-burner 130 and the second sub-burner 140. The total combustion amount can be adjusted within the range of 0.6 to 2.0. That is, the total of three is 1.6-
The combustion amount can be adjusted within the range of 3.0.

Therefore, by switching the number of burners by the burner switching mechanism 190 and adjusting the gas pressure by the gas pressure variable type gas governor 180, the combustion amount at the maximum supply gas pressure is set to 1
Besides, it can be continuously adjusted in the range of 1.3 to 3.0. From this, the combustion amount at the standard supply gas pressure is √ (2 / 2.5) = 0.
9. Since the combustion amount of the sub-burner does not change with the supply gas pressure, the combustion amount can be continuously adjusted within the range of 1.2 to 2.9 in addition to 0.9. Therefore, only by setting the appropriate temperature between 0.9 and 1.2 by adjusting the amount of water, the appropriate temperature can be obtained at other places by adjusting the amount of gas. The above 0.9
The value from ~ 1.2 is 1 when bringing the main burner to the maximum input (100%) at the standard supply gas pressure.
~ 1.3. Next, the hot water supply capacity with four burners is 8.
Explaining the case of No. 5, the amount of water needs to be adjusted to a combustion amount of 0.9 to 1.2 or 1 to 1.3, and there is a very small range in which the temperature can be adjusted only by the amount of water. Become.

FIG. 4 shows the hot water supply capacity of 8 burners.
In the case of No. 5, when the main burner is set to maximize the input (100%) at the standard supply gas pressure, the relationship between the temperature rise due to heating and the water amount at various standard combustion gas amounts It is shown. When only the main burner 120 is burned, the hot water supply capacity is 2.1, as shown by the solid line 401 at the bottom, and when burning the two main burners 120 and the first sub-burner 130, Variable gas pressure type gas governor 180
Can be adjusted within the range of solid line 402 to solid line 403. When all of the main burner 120, the first sub-burner 130, the second sub-burner 140, and the third sub-burner 145 are burnt, the hot water supply capacity is No. 4 to 8.5, and the amount of water is in the range shown by the solid line 404 to the solid line 405. It becomes possible to adjust the relationship between the temperature and the temperature rise. Therefore, for example, when the water temperature is 23 ° C., it is possible to continuously select the tapping water at 42 ° C. in the amount of tapping water per minute in the range of about 3.7 liters to 11.2 liters.

Further, since the fuel gas is supplied to the main burner 120 for transferring the fire from the pilot burner 110 without passing through the gas pressure variable type gas governor 180, when the gas pressure variable type gas governor 180 is adjusted to the minimum set value. However, stable ignition can be secured without being affected by the influence.

The first nozzle 1 for the main burner 120
Since the nozzle diameter of 62 is made smaller than the nozzle diameters of the nozzles 172 and 173 for the first sub-burner 130 and the second sub-burner 140, even if the fuel gas is supplied without going through the gas governor, the supply gas pressure fluctuates. On the other hand, deterioration of combustion of the main burner 120 can be suppressed to a small extent. That is, although there is a difference in the combustion amount of the main burner 120 between the maximum supply gas pressure and the minimum supply gas pressure, the combustion amount of the main burner 120 does not exceed the maximum allowable value at the maximum supply gas pressure, Since the main burner 120 does not pass through the gas pressure variable type gas governor, the pilot burner 11 is not affected no matter where the set pressure of the governor is.
It is possible to obtain the amount of gas required to secure reliable ignition due to a fire transfer from zero.

Further, although there is a fluctuation range of the combustion amount of the main burner 120 with respect to the fluctuation of the supply gas pressure, the main burner 120 is set to have the maximum input (100%) at the maximum supply gas pressure. When the maximum combustion amount is 1, the main burner is 1 and the sub-burner is 2 and there are a total of 3 burners, and the supply gas type is 13A-0 (depending on the gas type, the minimum supply gas pressure, standard, The maximum is different. The details are defined in JIS) Even if the minimum supply gas pressure is 2.5 (0.95 x 2 + 0.64),
In the case of a 4-burner configuration with one main burner and three sub-burners, 3.5 (0.95 x 3 + 0.64)
Becomes Therefore, in the case where the main burner 120 is also provided with a separate gas governor so that the main burner 120 always has the maximum input in the region above the minimum supply gas pressure, the number of burners is 2.9 (0. 95 x
When the number of burners is 4 in 3), the number of burners is 3.8 (0.95 × 4), so even if compared with this, it is possible to secure the capacity with practically no hindrance. That is, when the supply pressure of the fuel gas is the maximum supply gas pressure, the same capability can be obtained when the gas governor is provided. Further, even when the supply pressure of the fuel gas becomes the minimum supply gas pressure, the combustion amount of the main burner 120 can be secured to about two thirds of the maximum combustion gas. You can get about 8/9 ability. Further, in the case of the configuration of one main burner and three sub-burners, it is possible to obtain the capacity of about 11/12 of the maximum supply gas pressure at the minimum supply gas pressure, and the capacity fluctuation due to the difference in the supply gas pressure does not occur. Almost no problem.

As described above, the ignition performance and the ability at the time of the minimum supply gas pressure can be sufficiently secured without providing a separate gas governor for the main burner 120, so that the rise of the apparatus price due to the provision of the separate gas governor is prevented. It

Next, a second embodiment will be described.
In the first embodiment, as shown in FIGS. 5A and 5B, the fuel gas is supplied to the main burner 502 provided near the pilot burner 501 without passing through the gas governor, and the burner switching mechanism 503 is provided. The number of sub-burners 504 can be changed over and the variable gas pressure gas governor 505 is arranged upstream of the burner switching mechanism 503. On the other hand, in the combustion device according to the second embodiment, as shown in FIG.
As shown in FIG. 7, the sub-burner 504 is directly provided downstream of the gas pressure variable type gas governor 505 without providing the burner switching mechanism 503.
Are connected. As in the case of the first embodiment, the nozzle diameter of the nozzle for the main burner 502 is smaller than the nozzle diameter of the nozzle for the sub-burner 504, and at the maximum supply gas pressure or standard gas pressure. The main burner 502 is designed to have almost the maximum input.

In the structure shown in FIG. 6, assuming that the capacity of each burner at the time of maximum input is 1 and the capacity when the sub-burner 504 is at the minimum set value is 0.3, the maximum supply gas pressure is 1.6. It is possible to adjust the capacity continuously within the range of ~ 3. Further, at the lowest supply gas pressure, the capacity of the main burner 502 can be continuously adjusted within the range of 1.2 to 2.6 assuming that the input of the main burner 502 is reduced to about 64% of the maximum value. 71% for maximum input (100%) at standard supply gas pressure,
It becomes 1.3 to 2.7.

In the case of the second embodiment, the minimum value of the adjustment range increases because the burner switching mechanism 503 is not provided, but the number of burners connected downstream of the variable gas pressure type gas governor 505 is 1 to 2. With this level, it is possible to secure a sufficient variable capacity range for showering, and it is possible to discharge a suitable amount of hot water regardless of the incoming water temperature. In addition, regardless of the setting state of the gas pressure variable type gas governor 505 and the supply gas pressure, reliable fire transfer to the main burner 502 is ensured. Therefore, it is suitable for a type having three burners, for example, a hot water supply capacity of 6.5.

FIG. 7 shows a schematic structure of a combustion apparatus according to the third embodiment. In this example, the main burner 502 is in charge of the fire transfer from the pilot burner 501.
Also, the fuel gas is supplied through the gas pressure variable type gas governor 505. In this case, when the minimum regulated gas pressure in the gas pressure variable type gas governor 505 is set to about half of the maximum, the capacity can be varied almost continuously and stable ignition can be secured.

That is, when the fuel gas is supplied only to the main burner 502, the capacity can be adjusted within the range of 0.5 to 1.0. If one sub-burner 504 is added, the sub-burner 5 will be added in the range of 1.0 to 2.0.
When 04 is switched to two, the capacity can be adjusted within the range of 1.5 to 3.0. In other words, the ability can be adjusted within the range of 0.5 to 3.0 as a whole. Further, even when the set value of the gas pressure variable type gas governor 505 is minimized, the main burner 502 is supplied with 50% of the fuel gas at the maximum, so that almost reliable ignition performance can be secured. .

Further, when the set value of the gas pressure variable type gas governor 505 is minimized, the main burner 502 has a maximum of 6
Even if the fuel gas is set to be supplied at 0%, the combustion amount can be continuously changed within the ranges of 0.6 to 1.0 and 1.2 to 3.0. In the case of the third embodiment, the minimum value of the gas pressure variable type gas governor cannot be set too small, such as 0.5 or 0.6. However, unlike the second embodiment, it is possible to use a type in which the number of burners that can be connected downstream of the governor 505 is four, for example, a hot water supply capacity of 8.5 (embodiment (b)). When the minimum value of the governor 505 is set to 0.6, 0.6 to 1.0, 1.2 to 2.0, 2.4 to 4.0
The combustion amount can be changed continuously within the range.

For example, the combustion amount cannot be varied between 2.0 and 2.4. This is 4.25 in hot water supply capacity
No. 5.1 (4 = 8.5), and considering that the tap water temperature is 42 ° C. when the incoming water temperature is 23 ° C., it is 5.
It shows that the amount of tapping water between 6 liters and 6.7 liters cannot be obtained. Whether you pour hot water out of the faucet or shower it, 1-2 liters is not a sensational difference. Therefore, this embodiment is highly practical because it is a gap that does not hinder obtaining an appropriate temperature depending on the amount of water.

Next, the embodiment (C) will be described. This is an example of a hot water supply capacity of 8.5, for example, with eight burners in which one burner of the above-described embodiment is used as two burners having a small combustion capacity. In this case, the above-mentioned omission does not occur (0.9 to 1.5, 1.5 to 2.
5, 2.4-4) The combustion amount can be continuously changed within the range of 0.9-4.0.

The structure of the burner switching mechanism 190 shown in the embodiment described above is an example, and the present invention is not limited to this. An orifice may be formed instead of the nozzle. Furthermore, although the example of the minimum supply gas pressure = regulated gas pressure has been shown, the present invention is not limited to this, and the standard supply gas pressure = regulated gas pressure may be used.

[0079]

According to the combustion apparatus of the present invention, the switching of the number of burners by the manual operation and the gas amount adjustment by the manual operation are used together, so that the continuous and wide range of the thermal power can be adjusted, and the appropriate temperature and the appropriate amount can be obtained. It is possible to realize hot water discharge regardless of the incoming water temperature.

Further, the fuel gas is supplied to the main burner which is first ignited by the transfer of heat from the pilot burner without passing through the adjusting means, so that regardless of the set value of the adjusting means, that is, the adjusting means is the gas. Even if it is set to reduce the amount, stable ignition can be secured.

Further, a variable gas pressure type gas governor is used as the adjusting means, and fuel gas is supplied to the main burner without passing through the gas governor, and the diameter of the nozzle provided in the preceding stage of the main burner is set to be smaller than the diameter of the nozzle for the subburner. With a smaller value, there is a change in the amount of change in the combustion amount with respect to the supply gas pressure of the main burner, but even if the maximum combustion amount is set at the maximum gas pressure, stable ignition is achieved at the minimum gas pressure. It is possible to secure as much combustion amount as possible.

It should be noted that the nozzle diameter of the main burner nozzle is increased within a range in which the combustion amount of the main burner when the fuel gas is supplied at the assumed maximum gas pressure does not exceed the maximum combustion amount allowed by the main burner. If set, it is possible to secure almost the same combustion amount in the case of standard gas pressure as in the case where all the burners are provided with gas governors, and it is possible to secure more stable ignition even at the lowest gas pressure.

[Brief description of drawings]

FIG. 1 is a partial cross-sectional view showing a main part of a combustion device according to a first embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a relationship between a supply gas pressure and a nozzle gas pressure and a relationship between a supply gas pressure and a combustion amount in the combustion apparatus according to the first embodiment of the present invention.

FIG. 3 is an explanatory diagram showing the relationship between the supply gas pressure and the combustion amount when the nozzle diameter is set so that the maximum input is achieved at the supply gas pressure lower than the maximum supply gas pressure.

FIG. 4 is an explanatory diagram showing, for various combustion amounts, the relationship between the temperature rise due to heating and the amount of water in the combustion apparatus according to the first embodiment of the present invention.

FIG. 5 is a block diagram showing a schematic configuration of a combustion device according to the first embodiment of the present invention.

FIG. 6 is a block diagram showing a schematic configuration of a combustion device according to a second embodiment of the present invention.

FIG. 7 is a block diagram showing a schematic configuration of a combustion device according to a third embodiment of the present invention.

FIG. 8 is an explanatory diagram showing the relationship between the temperature rise and the amount of water in a burner number switching type combustion device that has been conventionally used.

FIG. 9 is a sectional view showing a main part of a burner number switching type combustion device which has been conventionally used.

FIG. 10 is an explanatory diagram showing the relationship between the position of the switching valve of the combustion apparatus according to the embodiment of the present invention, the open state of the flow path, and the number of burners supplied with fuel gas.

[Explanation of symbols]

100 ... Combustion device 110 ... Pilot burner 120 ... Main burner 130 ... First sub-burner 140 ... Second sub-burner 145 ... Third sub-burner 150 ... Gas distribution chamber 160 ... First gas chamber 161, 171 ... Gas inlet 162 ... First nozzle 170 ... Second gas chamber 172 ... Second nozzle 173 ... Third nozzle 174 ... Fourth nozzle 180 ... Gas governor with variable gas pressure 181 ... Diaphragm 182 ... valve seat 183 ... Valve 184 ... Support arm 185 ... Coil spring 186 ... Fine adjustment knob 187 ... Spring pedestal 190 ... Burner switching mechanism 191 ... Switching valve body 192 ... Valve seat body 193 ... Spring 194 ... Ability switching knob 195 ... Gas guideway 210 ... Top graph 220 ... Lower graph 501 ... Pilot burner 502 ... Main burner 503 ... Burner switching mechanism 504 ... Sub burner 505 ... Variable gas pressure type gas governor

Claims (8)

[Claims] 1. In a combustion apparatus having a plurality of burners, switching means for switching the number of burners to which fuel gas is supplied based on manual operation, and manual operation of the amount of fuel gas supplied to the burner. A combustor comprising: an adjusting unit that can be changed based on the above, and a manual adjustment of the thermal power by using the switching unit and the adjusting unit together. 2. The combustion apparatus according to claim 1, wherein the switching means is provided downstream of the adjusting means. 3. A combustion apparatus having a plurality of burners, comprising: a main burner, one or more sub-burners, a pilot burner for spark ignition, a switching means, and an adjusting means, wherein the adjusting means comprises: The gas amount of the fuel gas supplied to all or a part of the subburners can be changed based on a manual operation, and the switching means manually changes the number of the fuel gases supplied to the subburners. The main burner is arranged in the vicinity of the pilot burner so that the fuel can be supplied without going through the adjusting means and the fire can be transferred from the pilot burner without going through the adjusting means. Combustion device. 4. The combustion apparatus according to claim 3, wherein the switching means is provided downstream of the adjusting means. 5. In a combustion apparatus having a plurality of burners, adjusting means for changing the gas amount of fuel gas to be supplied to the burner based on manual operation, and supply of fuel gas via said adjusting means 1 Alternatively, the pilot burner may include two or more sub-burners, a main burner supplied with fuel gas without the adjustment means, and a pilot burner for igniting the pilot burner so that the main burner can transfer heat from the pilot burner. A combustion device characterized by being placed in the vicinity of the burner. 6. The gas pressure variable type gas governor capable of stabilizing the gas pressure of the fuel gas supplied to the burner to a predetermined set value and changing the set value based on a manual operation. Claims 1 and 2, characterized in that
The combustion device according to 3, 4, or 5. 7. The gas governor of variable gas pressure capable of stabilizing the gas pressure of the fuel gas supplied to the burner to a predetermined set value and changing the set value based on a manual operation. The main burner is supplied with the fuel gas without going through a gas governor for stabilizing the gas pressure of the fuel gas to a predetermined set value, and a nozzle for narrowing the flow passage cross-sectional area is provided in the front stage of each burner. The nozzle diameter of the nozzle provided in the front stage of the burner is made smaller than the nozzle diameter of the nozzle provided in the front stage of the sub-burner.
The combustion device according to 1. 8. The main burner is provided in a preceding stage within a range in which a combustion amount of the main burner when the fuel gas is supplied at an expected maximum gas pressure does not exceed a maximum combustion amount allowed by the main burner. The combustion apparatus according to claim 7, wherein the nozzle diameter of the nozzle is set to be large.